Mesenchymal stem cell and a method of use thereof

ABSTRACT

Demyelinated axons were remyelinated in the demyelinated rat model by collecting bone marrow cells from mouse bone marrow and transplanting the mononuclear cell fraction separated from these bone marrow cells.

TECHNICAL FIELD

The present invention relates to cells derived from bone marrow cells, cord blood cells, or embryonic hepatic tissues that can differentiate into neural cells, and cell fractions containing such cells. It is expected that these cells and cell fractions can be used to treat neurological diseases, particularly in autologous transplantation therapy.

BACKGROUND ART

Transplantation of oligodendrocytes (i.e., oligodendroglia) (Archer D. R., et al., 1994. Exp. Neurol. 125:268-77; Blakemore W. F., Crang A. J., 1988. Dev. Neurosci. 10:1-11; Gumpel M., et al. 1987. Ann. New York Acad. Sci. 495:71-85) or myelin-forming cells, such as Schwann cells (Blakemore W. F., 1977. Nature 266:68-9; Blakemore W. F., Crang A. J., 1988. Dev. Neurosci. 10:1-11; Honmou O. et al., 1996. J. Neurosci. 16:3199-208), or olfactory ensheating cells (Franklin R. J. et al., 1996. Glia 17:217-24; Imaizumi T. et al., 1998. J. Neurosci. 18(16):6176-6185; Kato T. et al., 2000. Glia 30:209-218), can elicit remyelination in animal models and recovery of electrophysiological function (Utzschneider D. A. et al., 1994. Proc. Natl. Acad. Sci. USA. 91:53-7; Honmou O. et al., 1996. J. Neurosci. 16:3199-208). It is possible to prepare such cells from patients or other persons for cell therapy. However, this method is considerably problematic because tissue material must be collected from either the brain or nerves.

Neural progenitor cells or stem cells derived from brain have the ability to self-renewal and differentiate into various lineages of neurons and glia cells (Gage F. H. et al., 1995. Proc. Natl. Acad. Sci. USA. 92:11879-83; Lois C., Alvarez-Buylla A., 1993. Proc. Natl. Acad. Sci. USA. 90:2074-7; Morshead C. M. et al., 1994. Neuron 13:1071-82; Reynolds B. A., Weiss S., 1992. Science 255:1707-10). By transplantation into newborn mouse brain, human neural stem cells collected from fetal tissues differentiate into neurons and astrocytes (Chalmers-Redman R. M. et al., 1997. Neurosci. 76:1121-8; Moyer M. P. et al., 1997. Transplant. Proc. 29:2040-1; Svendsen C. N. et al., 1997. Exp. Neurol. 148:135-46), and myelinate the axons (Flax J. D. et al., 1998. Nat. Biotechnol. 16:1033-9). Remyelination and recovery of impulse conduction upon transplantation of neural progenitor (stem) cells derived from adult human brain into demyelinated rodent spinal cord have been reported (Akiyama Y. et al., 2001. Exp. Neurol.).

These studies have evoked great interest due to the indicated possibility of the application of the above-mentioned cells to regenerative strategy of neurological diseases (Akiyama Y. et al., 2001. Exp. Neurol.; Chalmers-Redman R. M. et al., 1997. Neurosci. 76:1121-8; Moyer M. P. et al., 1997. Transplant. Proc. 29:2040-1; Svendsen C. N. et al., 1997. Exp. Neural. 148:135-46; Yandava B. D. et al., 1999. Proc. Natl. Acad. Sci. USA. 96:7029-34). However, in order to establish cell transplantation therapy (including autologous transplantation) using these cells, still problems, such as establishment of harvest method and requirement of cell expansion using trophic factors, remain to be solved.

According to the recent studies, neural stem cells were revealed to be able to differentiate or transform into hematopoietic cells in vivo, suggesting that neural progenitor (stem) cells are not restricted to the neural cell lineage (Bjornson C. R. et al., 1999. Science 283:534-7). Furthermore, bone marrow stromal cells (not mesenchymal stem cells in the bone marrow) are reported to differentiate into astrocytes by the injection into the lateral ventricles of neonatal mice (Kopen G. C. et al., Proc. Natl. Acad. Sci. USA. 96:10711-6), and into neurons in vitro when cultured under appropriate cell culture conditions (Woodbury D. et al., 2000. J. Neurosci. Res. 61:364-70).

DISCLOSURE OF THE INVENTION

The present inventors have previously isolated and cultured neural stem cells from adult human brain, and established some cell lines. By studying their functions, the inventors newly discovered that the neural stem cells have pluripotency and the ability to self-renewal. Specifically, single-cell expansion of neural progenitor (stem) cells obtained from adult human brain was conducted to establish cell lines; the established cells were then subjected to in vitro clonal analysis. The result showed that the cell lines had pluripotency (namely, differentiation into neuron, astroglia (or astrocyte), and oligodendroglia (i.e., oligodendrocyte)) and the ability to self-renewal (namely, proliferation potency). Thus, these cells were confirmed to possess the characteristics of neural stem cell.

Transplantation of these cells indeed resulted in very favorable graft survival, migration, and differentiation in cerebral ischemic model rats or injury model rats. Furthermore, transplantation of the cells was found to result in functional myelin sheath formation in spinal cord demyelination model rats. Thus, such transplantation allows remyelination of the demyelinated axon and restoration of the neural function in the rat spinal cord demyelination model. Effectiveness of such transplantation therapy using these cells was confirmed by histological, electrophysiological, and behavior studies.

Judging from the above-described findings, transplantation of cultured neural stem cells, which have been isolated from a small amount of neural tissue collected from the cerebrum of a patient, into the lesion of the brain or the spinal cord of the patient seems to be a widely applicable in autotransplantation therapy.

However, while not causing neurologic deficits, collecting tissues containing neural stem cells from cerebrum is relatively invasive. Thus, considering the need for establishing therapeutic methods for various complicated diseases in the nervous system today, it is crucial to establish a safer and simpler method for autotransplantation therapy.

Thus, an objective of the present invention is to provide cellular material that is useful in the treatment of neurological diseases, and which can be prepared safely and readily. Another objective of the present invention is to provide a method for treating neurological diseases, preferably a method for autotransplantation therapy, using the cellular material.

In view of the existing state as described above, to establish donor cells the present inventors focused on the technique of collecting bone marrow cells from bone marrow, a simpler technique as compared to the collection of neural stem cells and routinely used in today's medical practice. First, they collected bone marrow cells from mouse bone marrow, isolated mononuclear cell fraction, and then transplanted this fraction as donor cells into spinal cord demyelination model rats. Surprisingly, it was discovered that the demyelinated axon gets remyelination by the treatment. Hence, the present inventors newly revealed that the mononuclear cell fraction prepared from bone marrow cells have the ability to differentiate into neural cells. The present inventors also discovered that cell fractions containing mesodermal stem cells, mesenchymal stem cell, stromal cells, and AC133-positive cells, that were isolated from the mononuclear cell fraction had the ability to differentiate into neural cells. Besides bone marrow cells, these cell fractions can also be prepared from cord blood cells. Furthermore, AC133-positive cells can be prepared from embryonic hepatic tissues.

Thus, the present invention provides cell fractions containing cells capable of differentiating into neural cells, which are isolated from bone marrow cells, cord blood cells, and embryonic hepatic tissues.

In another embodiment, such cell fractions contain mesenchymal stem cells having the following character: SH2(+), SH3(+), SH4(+), CD29(+), CD44(+), CD14(−), CD34(−), and CD45(−).

In another embodiment, such cell fractions contain stromal cells having the following characteristics: Lin(−), Sca-1(+), CD10(+), CD11D(+), CD44(+), CD45(+), CD71(+), CD90(+), CD105(+), CDW123(+), CD127(+), CD164(+), fibronectin (+), ALPH (+), and collagenase-1(+).

In another embodiment, such cell fractions contain cells having the character AC133(+).

In addition, the present invention provides cells capable of differentiating into neural cells, which are contained in the above-mentioned cell fraction.

Furthermore, the present invention provides compositions for treating neurological disease, which contain the above-mentioned mononuclear cell fractions or the above-mentioned cells. According to a preferred embodiment of the present invention, the neurological disease is selected from the group consisting of: central and peripheral demyelinating diseases; central and peripheral degenerative diseases; cerebral apoplexy (cerebral infarction, cerebral hemorrhage, subarachnoid hemorrhage); brain tumor; dysfunction of higher function of the brain (the term “higher function of the brain” involves the cognitive function, short and long memory, speech, etc.); psychiatric diseases; dementia; infectious diseases; epilepsy; traumatic neurological diseases; and infarction of spinal cord diseases.

Furthermore, the present invention provides therapeutic methods for neurological diseases, which comprises transplanting of the above-mentioned mononuclear cell fractions, cells, or compositions. In preferred embodiments, the donor cells are derived from a recipient.

The present invention provides mononuclear cell fractions isolated from bone marrow cells, cord blood cells, or embryonic hepatic tissues, wherein the fractions contain cells capable of differentiating into neural cells. It is unclear whether the differentiation of cells contained in the cell fractions provided by the present invention into neural cells is caused by the transformation of so-called hematopoietic cells into neural cells, or, alternatively, by the differentiation of immature cells capable of differentiating into neural cells that are comprised in bone marrow cells, etc. However, the majority of the cells differentiating into neural cells are assumed to be stem or precursor cells, namely, cells having the self-renewal ability and pluripotency. Alternatively, the cells differentiating into neural cells may be stem or precursor cells which have differentiated to some extent into endoderm or mesoderm.

Cells in a cell fraction of the present invention do not have to be proliferated with any trophic factors (then again they can proliferate in the presence of trophic factors). Thus, these cells are simple and practical from the standpoint of the development of autotransplantation technique for the diseases in the neural, and are very beneficial in medical industry. In general, a cell fraction of the present invention is derived from vertebrate, preferably from mammal (for example, mouse, rat, human, etc.).

A cell fraction of the present invention can be prepared by subjecting bone marrow cells or cord blood cells collected from vertebrate to density-gradient centrifugation at 2,000 rpm in a solution for a sufficient time-ensuring separation depending on specific gravity, and then recovering the cell fraction with a certain specific gravity within the range of 1.07 to 1.1 g/ml. Herein, the phrase “a sufficient time ensuring separation depending on specific gravity” refers to a time sufficient for the cells to shift to a position in the solution according to their specific gravity, which is typically about 10 to 30 minutes. The specific gravity of the cell fraction to be recovered is within the range of 1.07 to 1.08 g/ml (for example, 1.077 g/ml). Solutions, such as Ficoll solution and Percoll solution, can be used for the density-gradient centrifugation, but is not limited thereto.

Specifically, first, bone marrow (5 to 10 μl) collected from a vertebrate is combined with a solution (2 ml L-15 plus 3 ml Ficoll), and then centrifuged at 2,000 rpm for 15 minutes to isolate a mononuclear cell fraction (approx. 1 ml) The mononuclear cell fraction is combined with culture solution (2 ml NPBM) to wash the cells, and then the cells are again centrifuged at 2,000 rpm for 15 minutes. Then, the precipitated cells are recovered after the removal of the supernatant. Besides femur, sources to obtain a cell fraction of the present invention include sternum, and ilium constituting the pelvis. Any other bone can serve as a source so long as it is large enough. A cell fraction of the present invention can also be prepared from bone marrows and cord blood stored in bone marrow bank or cord blood bank.

Another embodiment of cell fractions of the present invention includes a mononuclear cell fraction isolated and purified from bone marrow cells or cord blood cells, which contains mesodermal (mesenchymal) stem cells capable of differentiating into neural cells. The term “mesodermal (mesenchymal) stem cell” refers to cells that can copy (divide and proliferate) cells with the same potential as themselves and that are capable of differentiating into any type of cells constituting mesodermal (mesenchymal) tissues. Mesodermal (mesenchymal) cells indicate cells constituting tissues that are embryologically categorized to the mesoderms, including blood cells. The mesodermal (mesenchymal) stem cell includes, for example, cells characterized by SH2(+), SH3(+), SH4(+), CD29(+), CD44(+), CD14(−), CD34(−), and CD45(−). A cell fraction containing mesodermal (mesenchymal) stem cells can be obtained, for example, by selecting cells having a cell surface marker, such as SH2, as described above from the above-mentioned cell fraction obtained by centrifuging bone marrow cells or cord blood cells (the cell fraction according to claim 2).

Furthermore, a cell fraction containing mesodermal (mesenchymal) stem cells capable of differentiating into neural cells can be prepared by subjecting bone marrow cells or cord blood cells collected from vertebrate to density-gradient centrifugation at 900 G in a solution for a sufficient time ensuring separation depending on specific gravity, and then recovering the cell fraction with a certain specific gravity within the range of 1.07 to 1.1 g/ml. Herein, “a sufficient time ensuring separation depending on specific gravity” refers to a time sufficient for the cells to shift to a specific position corresponding to their specific gravity in the solution for density-gradient centrifugation, which is typically about 10 to 30 minutes. The specific gravity of a cell fraction to be recovered varies depending on the type of animal (for example, human, rat, and mouse) from which the cells have been derived. A solution to be used for density-gradient centrifugation includes Ficoll solution and Percoll solution, but is not limited thereto.

Specifically, first, bone marrow (25 ml) or cord blood collected from vertebrate is combined with an equal volume of PBS solution, and then centrifuge at 900 G for 10 minutes. Precipitated cells are mixed with PBS and then are recovered (cell density=approx. 4×10⁷ cells/ml) to remove blood components. Then, a 5-ml aliquot thereof is combined with Percoll solution (1.073 g/ml), and centrifuged at 900 G for 30 minutes to extract a mononuclear cell fraction. The extracted mononuclear cell fraction is combined with a culture solution (DMEM, 10% FBS, 1% antibiotic-antimycotic solution) to wash the cells, and is centrifuged at 2,000 rpm for 15 minutes. Finally, the supernatant is removed, precipitated cells are recovered and cultured at 37° C. under 5% CO² atmosphere.

Another embodiment of a cell fraction of the present invention is a fraction of mononuclear cells isolated from bone marrow cells or cord blood cells, which contains stromal cells capable of differentiating into neural cells. Examples of stromal cell include cells characterized by Lin(−), Sca-1(+), CD10(+), CD11D(+), CD44(+), CD45(+), CD71(+), CD90(+), CD105(+), CDW123(+), CD127(+), CD164(+), fibronectin (+), ALPH(+), and collagenase-1(+). A cell fraction containing stromal cells can be prepared, for example, by selecting cells having a cell surface marker, such as Lin as described above, from the above-mentioned cell fraction obtained by centrifuging bone marrow cells or cord blood cells (the cell fraction according to claim 2).

Furthermore, such a cell fraction can be prepared by subjecting bone marrow cells or cord blood cells collected from vertebrate to density-gradient centrifugation at 800 G in a solution for a sufficient time ensuring separation depending on specific gravity, and then recovering the cell fraction with a certain specific gravity within the range of 1.07 to 1.1 g/ml. Herein, “a sufficient time ensuring separation depending on the specific gravity” indicates a time sufficient for the cells to shift to a specific position corresponding to their specific gravity in the solution for density-gradient centrifugation, which is typically about 10 to 30 minutes. The specific gravity of a cell fraction to be recovered is preferably within the range of 1.07 to 1.08 g/ml (for example, 1.077 g/ml). A solution to be used for density-gradient centrifugation includes Ficoll solution and Percoll solution, but is not limited thereto.

Specifically, first, bone marrow or cord blood collected from vertebrate is combined with an equal volume of a solution (PBS, 2% BSA, 0.6% sodium citrate, and 1% penicillin-streptomycin). A 5-ml aliquot thereof is combined with Ficoll+Paque solution (1.077 g/ml) and centrifuged at 800 G for 20 minutes to obtain a mononuclear cell fraction. The mononuclear cell fraction is combined with a culture solution (Alfa MEM, 12.5% FBS, 12.5% horse serum, 0.2% i-inositol, 20 mM folic acid, 0.1 mM 2-mercaptoethanol, 2 mM L-glutamine, 1 μM hydrocortisone, 1% antibiotic-antimycotic solution) to wash the cells, and then are centrifuged at 2,000 rpm for 15 minutes. The supernatant is removed after centrifugation. The precipitated cells are collected and then cultured at 37° C. under 5% CO² atmosphere.

Another embodiment of a cell fraction of the present invention is a mononuclear cell fraction containing cells characterized by AC133(+) capable of differentiating into neural cells, which is isolated from bone marrow cells, cord blood cells, or embryonic hepatic tissues. Such a cell fraction can be obtained, for example, by selecting cells having a cell surface marker including the above-mentioned AC133(+) from the cell fraction obtained, as described above, by centrifuging bone marrow cells or cord blood cells (the cell fraction according to claim 2).

Furthermore, the cell fraction can be obtained by subjecting embryonic hepatic tissues collected from vertebrate to density-gradient centrifugation at 2,000 rpm in a solution for a sufficient time ensuring separation depending on specific gravity, recovering a cell fraction within the range of a specific gravity of 1.07 to 1.1 g/ml, and then recovering cells with the characteristic of AC133(+) from the cell fraction. Herein, “a sufficient time ensuring separation depending on specific gravity” indicates a time sufficient for the cells to shift to a specific position corresponding to their specific gravity in the solution for density-gradient centrifugation, which is typically about 10 to 30 minutes. The solution to be used for density-gradient centrifugation includes Ficoll solution and Percoll solution, but is not limited thereto.

Specifically, first, liver tissue collected from vertebrate is washed in L-15 solution, and then treated enzymatically in an L-15 solution containing 0.01% DNaseI, 0.25% trypsin, and 0.1% collagenase at 37° C. for 30 minutes. Then, the tissue is dispersed into single cells by pipetting. The single-dispersed embryonic hepatic cells are centrifuged by the same procedure as described for the preparation of the mononuclear cell fraction from femur in Example 1 (1). The cells thus obtained are washed, and then AC133(+) cells are collected from the washed cells using an AC133 antibody. Thus, cells capable of differentiating into neural cells can be prepared from embryonic hepatic tissues. The antibody-based recovery of AC133(+) cells can be achieved using magnetic beads or a cell sorter (FACS, etc.).

Transplantation of any of these cell fractions containing mesodermal stem cells, mesenchymal stem cells, stromal cells, or AC133-positive cells into demyelinated spinal cord can lead to efficient remyelination of the demyelinated region. In particular, the above-mentioned cell fraction containing mesenchymal stem cells can engraft favorably and differentiate into neural cells such as neurons or glia when transplanted into a stroke model or a cerebral infarction model.

The present invention also provides cells capable of differentiating into neural cells, which are contained in the above-mentioned cell fraction. These cells include, for example, neural stem cells, mesodermal stem cells, mesenchymal stem cells, stromal cells, and AC133-positive cells which are contained in the above-mentioned cell fraction, but are not limited thereto so long as they can differentiate into neural cells.

The present invention also provides compositions for treating neurological diseases, which comprise a cell fraction or cells of the present invention. It is possible, to transplant the cell fractions or cells of the present invention without modification. However, in order to improve the efficiency of therapy, they may be transplanted as compositions combined with various additives or introduced with genes. The preparation of compositions of the present invention may comprise, for example, (1) addition of a substance that improves the proliferation rate of cells included in a cell fraction of the present invention or enhances the differentiation of the cells into neural cells, or introducing a gene having the same effect; (2) addition of a substance that improves the viability of cells in a cell fraction of the present invention in damaged neural tissues, or introducing a gene having the same effect; (3) addition of a substance that inhibits adverse effects of damaged neural tissue on the cells in a cell fraction of the present invention, or introducing a gene having the same effect; (4) addition of a substance that prolongs the lifetime of donor cells, or introducing a gene having the same effect; (5) addition of a substance that modulates the cell cycle, or introducing a gene having the same effect; (6) addition of a substance to suppress the immunoreaction or inflammation, or introducing a gene having the same effect; (7) addition of a substance that enhances the energy metabolism, or introducing a gene having the same effect; (8) addition of a substance that improves the migration of donor cells in host tissues, or introducing a gene having the same effect; (9) addition of a substance that improves blood flow (including inductions of angiogenesis), or introducing a gene having the same effect; (10) addition of a substance that cure the infectious diseases, or introducing a gene having the same effect, or (11) addition of a substance that cure the tumors, or introducing a gene having the same effect, but is not limited thereto.

It is considered that the cells according to the present invention are immobilized in the bone marrow by a distinct mechanism involving a certain type of substance (proteins, etc.) and do not normally move out into the peripheral blood. Therefore, to make these cells enter the peripheral blood circulation, conventionally, they are removed from the bone marrow, and then administered intravenously. However, the studies conducted by the present inventors gradually elucidated the mechanism of immobilization of these cells in the bone marrow. The discovery made by the present inventors showed that these cells, which had been localized in the bone marrow, could be made to move out into the peripheral blood by intravenous injection of active factors, such as an antibody, a cytokine, chemicals, or a growth factor. That is, therapeutic effect of bone marrow transplantation that is similar to that of the aforementioned method can be expected from intravenous injection of an active factor, such as an antibody, a cytokine, chemicals, or a growth factor.

A cell fraction, cell, and composition of the present invention can be used for treating neurological diseases. Target neurological diseases for the therapy include, for example, central and peripheral demyelinating diseases; central and peripheral degenerative diseases; cerebral apoplexy (including cerebral infarction, cerebral hemorrhage, and subarachnoid hemorrhage); cerebral tumor; disorders of higher brain function including dementia; psychiatric diseases; epilepsy, traumatic neurological diseases (including head injury, cerebral contusion, and spinal cord injury); infectious diseases; and infarction of spinal cord, but are not limited thereto.

According to the present invention, cells derived from bone marrow cells of a recipient can be transplanted as donor cells (autotransplantation therapy). This has the following advantages: (1) low risk of rejection for the transplantation; and (2) no difficulty in using immunosuppressant. When autotransplantation therapy is arduous, then cells derived from other person or nonhuman animal may be used. Cells frozen for storage are also usable. The donor cells may be derived from cord blood.

Bone marrow can be collected, for example, by anesthetizing (by local or systemic anesthesia) an animal (including human) that serves as a source, put a needle into the sternum or iliac of the animal, and aspirating the bone marrow with a syringe. On the other hand, it is an established technique to collect cord blood at birth by putting needle directly into the umbilical cord, and aspirating the blood from the umbilical cord using syringe, and to store the blood.

Transplantation of cells into a patient can be performed, for example, by first filling a syringe with cells to be transplanted. Herein, the cells are suspended in an artificial cerebrospinal fluid or physiological saline. Then, the damaged neural tissue is exposed by surgery, and, with a needle, directly injecting the cells into the lesion. Due to high migrating potential of cells contained in a cell fraction of the present invention, they can migrate in the neural tissues. Hence, cells can be transplanted into a region adjacent to the lesion. Moreover, injection of the cells into the cerebrospinal fluid is also expected to be efficacious. In the case of the injection of the cells into the cerebrospinal fluid, the cells can be injected into a patient by typical lumbar puncture, without surgical operation only under local anesthetization. Thus, the patient can be treated in patient's sickroom (not in an operation room), which makes the method preferable. Alternatively, intravenous injection (including any systemic transplantations such as intravenous, intraarterial, selective intraarterial administration) of the cells is also expected to be effective. Thus, transplantation can be carried out by a procedure based on typical blood transfusion, which is advantageous in that the treatment can be performed in patient's sickroom.

Furthermore, due to their high migrating potential, cells in a cell fraction of the present invention can be used as a carrier (vector) for genes. For example, the cells are expected to be useful as a vector for gene therapy for various neurological diseases such as brain tumor.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows optical light micrographs of transections of dorsal column of the spinal cord, which had been prepared at 1-mm intervals. (A), normal axon; and (C), damaged demyelinated axon. Patterns of dorsal column observed at higher magnification are shown in (B) for normal axon and in (D) for demyelinated axon. Scale bars: 250 μM in (A) and (C); 10 μm in (B) and (D).

FIG. 2 shows microphotographs demonstrating the remyelination of rat spinal cord (A), after transplantation of adult mouse bone marrow cells; and (C), after transplantation of Schwann cells. Photomicrographs demonstrating remyelinated axon observed at higher magnification are shown in (B), after transplantation of bone marrow cells; and (D), after transplantation of Schwann cells. Scale bars: 250 μm in (A) and (C); 10 μm in (B) and (D).

FIG. 3 shows an electron micrograph of remyelinated axon after the transplantation of bone marrow into the dorsal columns. The tissue was treated with substrate X-Gal to detect transplanted bone marrow cells containing the P-galactosidase gene in the damaged tissues (the reaction product is indicated with arrow). When observed at higher magnification, basal lamina was found around the fibers (wedge-shaped mark; scale bar 1 μm). The presence of large cytoplasmic and nuclear regions and basal lamina in the transplanted cells indicates peripheral myelination.

BEST MODE FOR CARRYING OUT THE INVENTION

The present invention will be described in more detail below with reference to examples based on specific experiments.

Example 1 Preparation of Bone Marrow Cells and Schwann Cells

(1) Bone Marrow Mononuclear Cells

Mouse bone marrow cells (10 μl) were obtained from the femur of adult LacZ (a structural gene of β-galactosidase) transgenic mice (The Jackson Laboratory, Maine, USA). The collected sample was diluted in L-15 medium (2 ml) containing 3 ml Ficoll, and centrifuged at 2,000 rpm for 15 minutes. Cells were collected from the mononuclear cell fraction, and suspended in 2 ml serum-free medium (NPMM: Neural Progenitor cell Maintenance Medium). Following centrifugation (2,000 rpm, 15 min), the supernatant was removed, and precipitated cells were collected and re-suspended in NPMM.

(2) Schwann Cells

Primary Schwann cell cultures were established from the sciatic nerve of neonatal mouse (P1-3) according to the method of Honmou et al. (J. Neurosci., 16(10): 3199-3208, 1996). Specifically, cells were released from sciatic nerve by enzymatic and mechanical treatment. 8×10⁵ cells per plate were plated onto 100-mm² poly (L-lysine)-coated tissue culture plates and the cells were cultured in Dulbecco's modified Eagle's medium (DMEM) supplemented with 20% (vol/vol) fetal calf serum.

Example 2 Experimental Animal Preparation and Transplantation

(1) Preparation of Demyelinated Rat Model

Experiments were performed on 12 week old Wistar rats. A localized demyelinated lesion was created in the dorsal columns using X-ray irradiation and ethidium bromide injection (EB-X treatment). Specifically, rats were anesthetized with ketamine (75 mg/kg) and xylazine (10 mg/kg) i.p., and a surface dose of 40 Grays of X-ray was irradiated using Softex M-150 WZ radiotherapy machine (100 kV, 1.15 mA, SSD 20 cm, dose rate 200 cGy/min) on the spinal cord caudal to the tenth thoracic spine level (T-10) through a 2×4 cm opening in a lead shield (4 mm thick). Three days after X-ray irradiation, rats were anesthetized as above, and aseptic laminectomy of the eleventh thoracic spine (T-11) was conducted. A demyelinating lesion was generated by the direct injection of ethidium bromide (EB) into the dorsal columns via a glass micropipette whose end was drawn. 0.5 μl saline containing 0.3 mg/ml EB was injected at the depths of 0.7 and 0.4 mm.

(2) Transplantation of Stem or Progenitor Cells that can Differentiate or Transform into the Neural Lineages

3 days after the EB injection, 1 μl of the cell suspension (1×10⁴ cells/μl), which was obtained in Example 1, was injected into the middle of the E3-X-induced lesion. Transplanted rats were immunosuppressed with cyclosporin A (10 mg/kg/day).

Example 3 Histological Examination

Rats were deeply anesthetized by the administration of sodium pentobarbital (60 mg/kg, i.p.), and perfused through the heart cannula, first, with phosphate-buffer solution (PBS) and then with a fixative containing 2% glutaraldehyde and 2% paraformaldehyde in 0.14 M Sorensen's phosphate buffer, pH 7.4. Following in situ fixation for 10 minutes, the spinal cord was carefully excised, cut into 1 mm segments and kept in fresh fixative. The tissue was washed several times in Sorensen's phosphate buffer, post-fixed in 1% OsO₄ for 2 hours at 25° C., dehydrated by elevating the concentration of the ethanol solution, passed through propylene oxide and embedded in EPON. Then, the tissue was cut into sections (1 μm), counterstained with 0.5% methylene blue and 0.5% azure II in 0.5% borax, and examined under light microscope (Zeiss: Axioskop FS). Ultrathin sections were counterstained with uranyl and lead salts, and examined with JEOL JEM1200EX electron microscope (JEOL, Ltd., Japan) at 60 kV.

A 50×50 μm standardized region in the central core of the dorsal columns in the spinal cords near the site wherein the cells were initially injected was used for morphometric analysis. The numbers of remyelinated axons and cell bodies associated with the axons were counted within this region; and the density to square millimeters was calculated. Furthermore, the diameters of the axons and cell bodies, the number of cells with multi-lobular nuclei, and cells showing myelination were examined in the same standardized region. Measurements and counts were obtained from five sections per rat, and five rats (n=5) were analyzed for each experimental condition. All variances represent standard error (±SEM).

The dorsal column in the spinal cord mostly consists of myelinated axons (FIG. 1A, B). The proliferation of endogenous glial cells was inhibited by the irradiation of X-ray to the dorsal columns of the lumbar spinal cord. Further, by the administration of a nucleic acid chelator, ethidium bromide, glial cells such as oligodendrocytes were found damaged and local demyelination occurred. Such lesions generated according to this procedure are characterized by almost complete loss of endogenous glial cells (astrocytes and oligodendrocytes) and preservation of axons (FIG. 1C). Examination of the lesion with a light microscope under a higher magnification revealed that congested areas consisting of demyelinated axons are appositioned closely to one another separated by areas wherein the debris of myelin exist and wherein macrophages exist (FIG. 1D). The lesion occupied nearly the entire dorso-ventral extent of the dorsal columns 5 to 7 mm longitudinally. Almost none of the endogenous invasion of Schwann cells or astrocytes occurs till the sixth to eighth week. With the start of invasion, these glial cells begin to invade into the lesion from peripheral borders. Thus, a demyelinated and glial-free environment is present for at least 6 weeks in vivo.

Three weeks after transplantation of LacZ transgenic mouse bone marrow cells (BM) into the central region of the lesion in immunosuppressed and demyelinated rat models, extensive remyelination of the demyelinated axons was observed (FIGS. 2A and 2B). Remyelination was observed across the entire coronal dimension of the dorsal columns and throughout the antero-posterior extent of the lesion. FIGS. 2C and 2D show the pattern of remyelination observed after transplantation of allogeneic Schwann cells (SC) into the EB-X lesion model. It is remarkable that large nuclear and cytoplasmic regions were found around the remyelinated axons, a characteristic of peripheral myelin, by both BM and SC transplantations.

Example 4 Detection of O-Galactosidase Reaction Products In Vivo

Three weeks after transplantation, β-galactosidase expressing myelin-forming cells were detected in vivo. Spinal cords were collected and fixed in 0.5% glutaraldehyde in phosphate-buffer for 1 h. Sections (100 μm) were cut with a vibratome and β-galactosidase expressing myelin-forming cells were detected by incubating the sections at 37° C. overnight with X-Gal (substrate which reacts with β-galactosidase to develop color) at a final concentration of 1 mg/ml in X-Gal developer (35 mM K₃Fe(CN)₆/35 mM K₄Fe(CN)₆3H₂O/2 mM MgCl₂ in phosphate-buffered saline) to form blue color within the cell. Sections were then fixed for an additional 3 h in 3.6% (vol/vol) glutaraldehyde in phosphate-buffer (0.14 M), and were examined with light microscope for the presence of blue reaction product (β-galactosidase reaction product). Prior to embedding in EPON, the tissue was treated with 1% OsO₄, dehydrated in a graded series of ethanol, and soaked in propylene oxide for a short period. Ultrathin sections were then examined under an electron microscope without further treatment.

Under the electron microscope, most of the myelin-forming cells derived from donor cells retained the basal membrane (FIG. 3: wedge-shaped mark). Additionally, the myelin-forming cells had relatively large nucleus and cytoplasm, which suggests the formation of a peripheral nervous system-type myelin sheath.

It was confirmed that almost no endogenous remyelination by oligodendrocytes or Schwann cells Occurs for at least six weeks in the lesion model used in the present experiment. Furthermore, the donor cells that contained the reporter gene LacZ, i.e., X-Gal-positive cells, were observed to form myelin at the electron microscopic level (FIG. 3: arrow).

Differentiation into neurons and glial cells could be observed following the transplantation of bone marrow cells into the EB-X lesions, but not by SC transplantation. Five percent of lacZ-positive cells (transplanted bone marrow cells) in the EB-X lesions showed NSE (Neuron Specific Enolase)-immunoreactivity and 3.9% showed GFAP (Glial Fibrially Acidic Protein)-immunoreactivity indicating that some of the bone marrow cells can differentiate into neurons or glial cells, respectively, in vivo.

Furthermore, employing antibodies, the present inventors isolated mesenchymal stem cells with the characteristic of cell markers SH2(+), SH3(+), CD29(+), CD44(+), CD14(−), CD34(−), and CD45(−) from the cell fraction obtained in Example 1 (1). Furthermore, they discovered that transplantation of the cells into the demyelinated regions of rat spinal cord results in more efficient remyelination. It was also revealed that the cells survived favorably and differentiated into neurons or neuronal cells and glia cells when transplanted into cerebral infarction model rats.

Further, the present inventors isolated stromal cells characterized by the cell surface markers Lin (−), Sca-1(+), CD10(+), CD11D (+), CD44(+), CD45(+), CD71(+), CD90(+), CD105(+), CDW123(+), CD127(+), CD164(+), fibronectin (+), ALPH (+), and collagenase-1(+) from the cell fraction obtained in Example 1 (1). Transplantation of the cells into demyelinated regions of rat spinal cord also resulted in efficient remyelination.

Further, the present inventors isolated cells characterized by the cell surface marker AC133(+) from the cell fraction obtained in Example 1 (1). Transplantation of the cells into demyelinated regions of rat spinal cord also resulted in efficient remyelination.

In addition, the present inventors obtained a cell fraction containing AC133-positive cells capable of differentiating into neural cells from rat embryonic hepatic tissues by the following procedure. Specifically, first, liver tissues collected from rat fetuses were washed in L-15 solution, and then treated enzymatically in L-15 solution containing 0.01% DNaseI, 0.25% trypsin, and 0.1% collagenase at 37° C. for 30 minutes. Then, the tissue was dispersed into single cells by pipetting several times. The single-dispersed embryonic hepatic tissues were centrifuged as in Example 1 (1) (preparation of mononuclear cell fraction from femur) to isolate a mononuclear cell fraction. The obtained mononuclear cell fraction was washed, and then, AC133(+) cells were recovered from the cell fraction using anti-AC133 antibody. The isolation of AC133-positive cells can be achieved using magnetic beads or a cell sorter (FACS or the like). Transplantation of the obtained AC133-positive cells into demyelinated regions of rat spinal cord also resulted in efficient remyelination.

INDUSTRIAL APPLICABILITY

As described above, the present invention provides fractions of mononuclear cells isolated and purified by collecting bone marrow-derived bone marrow cells, cord blood-derived cells, or fetal liver-derived cells. Transplantation of such mononuclear cell fractions into a demyelination model animal was confirmed to result in remyelination of the demyelinated axon.

Cells for transplantation can be relatively easily isolated from a small quantity of bone marrow cell fluid aspirated from bone marrow, and can be prepared for transplantation in several tens of minutes after the cells are being collected. Thus, these cells can serve as useful and regenerable cellular material for autotransplantation in the treatment of demyelinating diseases.

This invention highlights the development of the autotransplantation technique to treat demyelinating diseases in the central nervous system. Furthermore, the use of the present invention in transplantation and regeneration therapy for more general and diffuse damage in the nervous system is envisaged. In other words, this invention sheds light on autotransplantation therapy against ischemic cerebral damage, traumatic cerebral injury, cerebral degenerating diseases, and metabolic neurological diseases in the central and peripheral nervous systems.

According to the present invention, cells in the hematopoietic system (bone marrow or cord blood) are used as donor cells. Thus, to treat neurological diseases, the cells may be transplanted into the vessels instead of directly transplanting them into neural tissues. Specifically, donor cells transplanted into a vessel can migrate to the neural tissues and thereby regenerate the neural tissues. Hence, the present invention is a breakthrough in developing a therapeutic method for relatively noninvasive transplantation.

Furthermore, the present invention adds significantly to elucidate the mechanism underlying the differentiation of non-neural cells such as hematopoietic cells and mesenchymal, cells into neural cells. When genes determining the differentiation are identified and analyzed, use of such genes will allow efficient transformation of a sufficient quantity of non-neural cells such as hematopoietic cells and mesenchymal cells in a living body to neural cells. Thus, the present invention is a breakthrough in the field of “gene therapy” for inducing regeneration of neural tissues. 

1-16. (canceled)
 17. A cell population isolated from bone marrow or cord blood comprising mesenchymal stem cells that are SH2(+), SH3(+), SH4(+), CD29(+), CD44(+), CD14(−), CD34(−), and CD45(−), wherein cells within said cell population differentiate into neurons or glia cells after transplantation into a patient.
 18. A method for treating neurodegeneration, comprising isolating the cell population of claim 1, wherein said isolation does not exclude hematopoietic cells from said cell population; and injecting an effective amount of said isolated cell population into a patient in need of said treatment, wherein said effective amount of said isolated cell population is effective at treating said patient's neurodegeneration.
 19. The method for treating neurodegeneration according to claim 18, wherein said neurodegeneration is caused by nerve demyelination.
 20. The method for treating neurodegeneration according to claim 18, wherein said cell population is injected intra-arterially.
 21. The method for treating neurodegeneration according to claim 18, wherein said cell population is injected intravenously.
 22. The method for treating neurodegeneration according to claim 21, wherein said cell population is injected into the carotid artery.
 23. The method for treating neurodegeneration according to claim 18, wherein cells within said injected cell population differentiate into neuron or glia cells at a site of neurodegeneration.
 24. The method for treating neurodegeneration according to claim 18, wherein said neurodegeneration is caused by ischemia.
 25. The method for treating neurodegeneration according to claim 24, wherein said neurodegeneration caused by ischemia is stroke.
 26. The method for treating neurodegeneration according to claim 18, wherein said neurodegeneration is caused by demyelination or trauma.
 27. The method for treating neurodegeneration according to claim 26, wherein said trauma is caused by spinal cord injury or brain injury.
 28. The method for treating neurodegeneration according to claim 26, wherein said demyelination is caused by spinal cord injury or multiple sclerosis.
 29. The method for treating neurodegeneration according to claim 18, wherein said neurodegeneration is associated with Alzheimer's disease, Parkinson's disease, Huntington's disease, or amyotrophic lateral sclerosis (ALS). 